/* _______ ____ __ ___ ___ * \ _ \ \ / \ / \ \ / / ' ' ' * | | \ \ | | || | \/ | . . * | | | | | | || ||\ /| | * | | | | | | || || \/ | | ' ' ' * | | | | | | || || | | . . * | |_/ / \ \__// || | | * /_______/ynamic \____/niversal /__\ /____\usic /| . . ibliotheque * / \ * / . \ * resamp3.inc - Resampling helper template. / / \ \ * | < / \_ * By Bob and entheh. | \/ /\ / * \_ / > / * In order to find a good trade-off between | \ / / * speed and accuracy in this code, some tests | ' / * were carried out regarding the behaviour of \__/ * long long ints with gcc. The following code * was tested: * * int a, b, c; * c = ((long long)a * b) >> 16; * * DJGPP GCC Version 3.0.3 generated the following assembly language code for * the multiplication and scaling, leaving the 32-bit result in EAX. * * movl -8(%ebp), %eax ; read one int into EAX * imull -4(%ebp) ; multiply by the other; result goes in EDX:EAX * shrdl $16, %edx, %eax ; shift EAX right 16, shifting bits in from EDX * * Note that a 32*32->64 multiplication is performed, allowing for high * accuracy. On the Pentium 2 and above, shrdl takes two cycles (generally), * so it is a minor concern when four multiplications are being performed * (the cubic resampler). On the Pentium MMX and earlier, it takes four or * more cycles, so this method is unsuitable for use in the low-quality * resamplers. * * Since "long long" is a gcc-specific extension, we use LONG_LONG instead, * defined in dumb.h. We may investigate later what code MSVC generates, but * if it seems too slow then we suggest you use a good compiler. * * FIXME: these comments are somewhat out of date now. */ int32 dumb_resample(DUMB_RESAMPLER *resampler, sample_t *dst, int32 dst_size, VOLUME_PARAMETERS, double delta) { int dt; int VOLUME_VARIABLES; long done; long todo; LONG_LONG todo64; int quality; if (!resampler || resampler->dir == 0) return 0; ASSERT(resampler->dir == -1 || resampler->dir == 1); done = 0; dt = (int)(delta * 65536.0 + 0.5); if (dt == 0 || dt == 0x80000000) return 0; SET_VOLUME_VARIABLES; if (VOLUMES_ARE_ZERO) dst = NULL; init_cubic(); quality = resampler->quality; while (done < dst_size) { if (process_pickup(resampler)) { RETURN_VOLUME_VARIABLES; return done; } if ((resampler->dir ^ dt) < 0) dt = -dt; if (resampler->dir < 0) todo64 = ((((LONG_LONG)(resampler->pos - resampler->start) << 16) + resampler->subpos - dt) / -dt); else todo64 = ((((LONG_LONG)(resampler->end - resampler->pos) << 16) - resampler->subpos - 1 + dt) / dt); if (todo64 < 0) todo = 0; else if (todo64 > dst_size - done) todo = dst_size - done; else todo = (long) todo64; done += todo; { SRCTYPE *src = resampler->src; long pos = resampler->pos; int subpos = resampler->subpos; long diff = pos; long overshot; if (resampler->dir < 0) { if (!dst) { /* Silence or simulation */ LONG_LONG new_subpos = subpos + (LONG_LONG)dt * todo; pos += (long)(new_subpos >> 16); subpos = (long)new_subpos & 65535; } else if (quality <= DUMB_RQ_ALIASING) { /* Aliasing, backwards */ SRCTYPE xbuf[2*SRC_CHANNELS]; SRCTYPE *x = &xbuf[0]; SRCTYPE *xstart; COPYSRC(xbuf, 0, resampler->X, 1); COPYSRC(xbuf, 1, resampler->X, 2); while (todo && x < &xbuf[2*SRC_CHANNELS]) { // TODO: check what happens when multiple tempo slides occur per row HEAVYASSERT(pos >= resampler->start); MIX_ALIAS(+=, 1, 0); subpos += dt; pos += subpos >> 16; x -= (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; todo--; } x = xstart = &src[pos*SRC_CHANNELS]; LOOP4(todo, MIX_ALIAS(+=, 1, 2); subpos += dt; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; ); pos += DIVIDE_BY_SRC_CHANNELS((long)(x - xstart)); } else if (quality <= DUMB_RQ_LINEAR) { /* Linear interpolation, backwards */ SRCTYPE xbuf[3*SRC_CHANNELS]; SRCTYPE *x = &xbuf[1*SRC_CHANNELS]; COPYSRC(xbuf, 0, resampler->X, 1); COPYSRC(xbuf, 1, resampler->X, 2); COPYSRC(xbuf, 2, src, pos); while (todo && x < &xbuf[3*SRC_CHANNELS]) { HEAVYASSERT(pos >= resampler->start); MIX_LINEAR(+=, 1, 0, -1); subpos += dt; pos += subpos >> 16; x -= (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; todo--; } // TODO: use xstart for others too x = &src[pos*SRC_CHANNELS]; LOOP4(todo, HEAVYASSERT(pos >= resampler->start); MIX_LINEAR(+=, 1, 1, 2); subpos += dt; pos += subpos >> 16; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; ); } else { /* Cubic interpolation, backwards */ SRCTYPE xbuf[6*SRC_CHANNELS]; SRCTYPE *x = &xbuf[3*SRC_CHANNELS]; COPYSRC(xbuf, 0, resampler->X, 0); COPYSRC(xbuf, 1, resampler->X, 1); COPYSRC(xbuf, 2, resampler->X, 2); COPYSRC(xbuf, 3, src, pos); if (pos-1 >= resampler->start) COPYSRC(xbuf, 4, src, pos-1); if (pos-2 >= resampler->start) COPYSRC(xbuf, 5, src, pos-2); while (todo && x < &xbuf[6*SRC_CHANNELS]) { HEAVYASSERT(pos >= resampler->start); MIX_CUBIC(+=, 1, x, x, 0, -1, -2, -3); subpos += dt; pos += subpos >> 16; x -= (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; todo--; } x = &src[pos*SRC_CHANNELS]; LOOP4(todo, HEAVYASSERT(pos >= resampler->start); MIX_CUBIC(+=, 1, x, x, 0, 1, 2, 3); subpos += dt; pos += subpos >> 16; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; ); } diff = diff - pos; overshot = resampler->start - pos - 1; if (diff >= 3) { COPYSRC2(resampler->X, 0, overshot < 3, src, pos+3); COPYSRC2(resampler->X, 1, overshot < 2, src, pos+2); COPYSRC2(resampler->X, 2, overshot < 1, src, pos+1); } else if (diff >= 2) { COPYSRC(resampler->X, 0, resampler->X, 2); COPYSRC2(resampler->X, 1, overshot < 2, src, pos+2); COPYSRC2(resampler->X, 2, overshot < 1, src, pos+1); } else if (diff >= 1) { COPYSRC(resampler->X, 0, resampler->X, 1); COPYSRC(resampler->X, 1, resampler->X, 2); COPYSRC2(resampler->X, 2, overshot < 1, src, pos+1); } } else { if (!dst) { /* Silence or simulation */ LONG_LONG new_subpos = subpos + (LONG_LONG)dt * todo; pos += (long)(new_subpos >> 16); subpos = (long)new_subpos & 65535; } else if (quality <= DUMB_RQ_ALIASING) { /* Aliasing, forwards */ SRCTYPE xbuf[2*SRC_CHANNELS]; SRCTYPE *x = &xbuf[0]; SRCTYPE *xstart; COPYSRC(xbuf, 0, resampler->X, 1); COPYSRC(xbuf, 1, resampler->X, 2); while (todo && x < &xbuf[2*SRC_CHANNELS]) { HEAVYASSERT(pos < resampler->end); MIX_ALIAS(+=, 1, 0); subpos += dt; pos += subpos >> 16; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; todo--; } x = xstart = &src[pos*SRC_CHANNELS]; LOOP4(todo, MIX_ALIAS(+=, 1, -2); subpos += dt; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; ); pos += DIVIDE_BY_SRC_CHANNELS((long)(x - xstart)); } else if (quality <= DUMB_RQ_LINEAR) { /* Linear interpolation, forwards */ SRCTYPE xbuf[3*SRC_CHANNELS]; SRCTYPE *x = &xbuf[1*SRC_CHANNELS]; COPYSRC(xbuf, 0, resampler->X, 1); COPYSRC(xbuf, 1, resampler->X, 2); COPYSRC(xbuf, 2, src, pos); while (todo && x < &xbuf[3*SRC_CHANNELS]) { HEAVYASSERT(pos < resampler->end); MIX_LINEAR(+=, 1, -1, 0); subpos += dt; pos += subpos >> 16; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; todo--; } x = &src[pos*SRC_CHANNELS]; LOOP4(todo, HEAVYASSERT(pos < resampler->end); MIX_LINEAR(+=, 1, -2, -1); subpos += dt; pos += subpos >> 16; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; ); } else { /* Cubic interpolation, forwards */ SRCTYPE xbuf[6*SRC_CHANNELS]; SRCTYPE *x = &xbuf[3*SRC_CHANNELS]; COPYSRC(xbuf, 0, resampler->X, 0); COPYSRC(xbuf, 1, resampler->X, 1); COPYSRC(xbuf, 2, resampler->X, 2); COPYSRC(xbuf, 3, src, pos); if (pos+1 < resampler->end) COPYSRC(xbuf, 4, src, pos+1); if (pos+2 < resampler->end) COPYSRC(xbuf, 5, src, pos+2); while (todo && x < &xbuf[6*SRC_CHANNELS]) { HEAVYASSERT(pos < resampler->end); MIX_CUBIC(+=, 1, x, x, -3, -2, -1, 0); subpos += dt; pos += subpos >> 16; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; todo--; } x = &src[pos*SRC_CHANNELS]; LOOP4(todo, HEAVYASSERT(pos < resampler->end); MIX_CUBIC(+=, 1, x, x, -3, -2, -1, 0); subpos += dt; pos += subpos >> 16; x += (subpos >> 16) * SRC_CHANNELS; subpos &= 65535; ); } diff = pos - diff; overshot = pos - resampler->end; if (diff >= 3) { COPYSRC2(resampler->X, 0, overshot < 3, src, pos-3); COPYSRC2(resampler->X, 1, overshot < 2, src, pos-2); COPYSRC2(resampler->X, 2, overshot < 1, src, pos-1); } else if (diff >= 2) { COPYSRC(resampler->X, 0, resampler->X, 2); COPYSRC2(resampler->X, 1, overshot < 2, src, pos-2); COPYSRC2(resampler->X, 2, overshot < 1, src, pos-1); } else if (diff >= 1) { COPYSRC(resampler->X, 0, resampler->X, 1); COPYSRC(resampler->X, 1, resampler->X, 2); COPYSRC2(resampler->X, 2, overshot < 1, src, pos-1); } } resampler->pos = pos; resampler->subpos = subpos; } } RETURN_VOLUME_VARIABLES; return done; } void dumb_resample_get_current_sample(DUMB_RESAMPLER *resampler, VOLUME_PARAMETERS, sample_t *dst) { int VOLUME_VARIABLES; SRCTYPE *src; long pos; int subpos; int quality; SRCTYPE *x; if (!resampler || resampler->dir == 0) { MIX_ZEROS(=); return; } ASSERT(resampler->dir == -1 || resampler->dir == 1); if (process_pickup(resampler)) { MIX_ZEROS(=); return; } SET_VOLUME_VARIABLES; if (VOLUMES_ARE_ZERO) { MIX_ZEROS(=); return; } init_cubic(); quality = resampler->quality; src = resampler->src; pos = resampler->pos; subpos = resampler->subpos; x = resampler->X; if (resampler->dir < 0) { HEAVYASSERT(pos >= resampler->start); if (dumb_resampling_quality <= DUMB_RQ_ALIASING) { /* Aliasing, backwards */ MIX_ALIAS(=, 0, 1); } else if (quality <= DUMB_RQ_LINEAR) { /* Linear interpolation, backwards */ MIX_LINEAR(=, 0, 2, 1); } else { /* Cubic interpolation, backwards */ MIX_CUBIC(=, 0, src, x, pos, 2, 1, 0); } } else { HEAVYASSERT(pos < resampler->end); if (dumb_resampling_quality <= DUMB_RQ_ALIASING) { /* Aliasing */ MIX_ALIAS(=, 0, 1); } else if (dumb_resampling_quality <= DUMB_RQ_LINEAR) { /* Linear interpolation, forwards */ MIX_LINEAR(=, 0, 1, 2); } else { /* Cubic interpolation, forwards */ MIX_CUBIC(=, 0, x, src, 0, 1, 2, pos); } } } #undef MIX_ZEROS #undef MIX_CUBIC #undef MIX_LINEAR #undef MIX_ALIAS #undef VOLUMES_ARE_ZERO #undef SET_VOLUME_VARIABLES #undef RETURN_VOLUME_VARIABLES #undef VOLUME_VARIABLES #undef VOLUME_PARAMETERS #undef SUFFIX3